Outcomes: Returns to education (occupational SEI and household income)

Occupational prestige is measured using the Duncan socio-economic index (SEI) score; if the respondent is not currently working, previous SEI is used. Household income is censored at $300,000 in MIDUS. Because within-pair differences in household income follow an approximately normal distribution, raw household income is used. I do not report results for individual respondent's income here due to higher rates of non-response, though they yielded similar findings (available on request).

Education

MIDUS asks respondents to report their final educational attainment in terms of credential points (e.g., completion of high school, General Equivalency Diploma (GED), Associate's degree, Bachelor's, Master's, or doctorate) or partial progress toward credentials (e.g., some high school, 1 or 2 years of college). For main analyses involving years of schooling, I recoded this measure to years of education (4–20 years). For supplementary analysis using level of schooling, I instead reduced the variable to five key categories (less than high school, high school, some college, college, and graduate).

Discordance predictor variables: Within- and between-twin-pair exposures

To predict within-pair education discordance I draw on established, basic determinants of educational attainment (e.g., Astone & McLanahan, Reference Astone and McLanahan1991; Conti & Hansman, Reference Conti and Hansman2013; McLeod & Fettes, Reference McLeod and Fettes2007; Sewell et al., Reference Sewell, Haller and Portes1969). Given that these determinants are important to understanding differences in attainment between unrelated individuals, they should extend to understanding differences between related individuals who differ in childhood conditions. To the extent that twins differ in this respect, they are expected to differ on educational attainment as well. Indeed, many of these variables have already been used to explain differences in attainment among siblings and twins.Footnote ²

Childhood peer, academic, familial and social environment (within twin pairs)

While identical twins share many aspects of their childhood environment, they also have unshared exposures. I measure these unshared exposures using a set of variables referring to peer, academic, familial, and social exposures. To begin, twins were asked whether they shared the same playmates and same classrooms as their co-twin growing up (never, sometimes, most of the time, or always). Most twins selected ‘always’ or ‘most of the time’ for these two items, so I contrast these two categories with all other categories.

Familial exposures include time spent in joint living spaces and similarity of exposure to parenting. Most identical twins reporting sharing a bedroom for between 16 and 18 years during childhood, so I contrast these twins with those who did not. Also, I consider whether twins lived together for fewer than 18 years (1 = yes, 0 = no). Finally, I consider differential exposure to parental discipline, in terms of strictness, consistency, harshness, and restrictiveness (four items; queried separately by parent, alphas = 0.77 and 0.83). For each twin, a parental discipline score is generated by averaging across maternal and paternal discipline or taking the available value when one is missing.

In terms of social exposures, twins assessed whether distant relatives or acquaintances had difficulty telling them apart (never, sometimes, most of the time, and always). Again, due to a highly skewed response distribution, I focus here on ‘always’ or ‘most of the time’. Others’ difficulty differentiating between co-twins measures the extent to which twins present themselves differently to others and also the extent to which others perceive (or are motivated to perceive) the twins as different. In other words, this is likely to tap differences in appearance, interpersonal behavior, and/or non-cognitive skills, all of which carry plausible links to eventual differences in schooling.

In addition to environmental exposures, biological and health differences are also core considerations for understanding adult socio-economic attainment. Twins were asked to report on their exact weight at birth (pounds and ounces). About 50% of identical twins reported their birth weight; analyses described later examined robustness to missing data on birth weight (see McFarland et al., Reference McFarland, Wagner and Marklin2016, for a similar strategy). Twins also rated whether they had similar weight during most of their childhood (within 10 pounds of each other, yes or no). Differences in childhood weight reflect differences in non-cognitive, cognitive, and peer factors once conditioned on socio-economic differences (von Hippel & Lynch, Reference von Hippel and Lynch2014). Twins also reported the ages at which they began smoking or drinking regularly; I focus on any between-twin differences in childhood or adolescent initiation by coding initiation at or before 18 years (1 = yes, 0 = no). Finally, twins reported on their overall mental health at age 16 years (poor, fair, good, very good, or excellent). I focus on whether the twins differed by more than one unit in reported adolescent mental health (1 = yes, 0 = no).

Demographic and parental variables (family level, between twin pairs)

At the twin-pair level, I consider sex, age, and race. I also consider parental socio-economic status, in terms of parental education and parental SEI. I focus on the maximum attained level of education across both parents (less than high school, high school, some college, college, and graduate), and I focus on the general level of maximum parental SEI (high = top 50% SEI in MIDUS sample, moderate = 25th to 50th percentile). A categorical SEI approach recognizes the fact that incremental, unit-wise gains in SEI generally are not relevant to understanding broad patterns in twin educational discordance, but that qualitative differences in SEI (e.g., professional or managerial vs. clerical or manual) are relevant. To capture severe economic deficiencies, I also consider whether the twins’ family ever received welfare during childhood. Finally, I included a measure of parental health when the respondent's age was 16 years (excellent, very good, good, fair, or poor).

To capture geographic variation in college completion rates, I indicate whether twin families grew up in a predominantly rural or small-town setting. Since moves during childhood tend to uproot peer relationships and schooling arrangements and may induce within-pair differences in schooling processes (Pribesh & Downey, Reference Pribesh and Downey1999; South & Haynie, Reference South and Haynie2004), I also considered how many times the family moved to a new neighborhood or town during childhood, up to a maximum of four times.

Treatment equation: Specification and estimation

The classic approach using identical twins to estimate the causal effect of a treatment, T, begins with a linear equation specifying the outcome, Y, as a function of genetic, G, family, F, and idiosyncratic, U, components:

(1) $$\begin{equation} {Y_{ij}} = {\theta _1}{G_i} + {\theta _2}{F_i} + \gamma {T_{ij}} + {U_{ij}}. \end{equation}$$

Here, i indexes families (twin pairs) and j indexes individuals. Because MZ twins are genetically identical and share the same family environment, I can take the difference among each pair of twins and write

(2) $$\begin{equation} \begin{array}{@{}l@{}} \Delta {Y_i} = \gamma \Delta {T_i} + \Delta {U_i} \equiv \\ \Delta {Y_i} = \gamma {D_i} + {V_i}. \end{array} \end{equation}$$

Under the assumption that D is independent of V (i.e., D⊥V), γ is the causal effect of T on Y. A weaker assumption is that D is conditionally independent of V, given observed predictors of D, that is,

(3) $$\begin{equation} {D_i} = {X'_i}\beta + {\varepsilon _i} \end{equation}$$

and ε⊥V. In this case, by conditioning on the X’s, I can recover the causal effect of T on Y.

The analysis starts with equation (3). Given the small number of values of D in data, I write the probability that D takes the specific value k (where k, educational discordance, may be 1 or 2 years or levels of education), as a linear function of predictors:

(4) $$\begin{equation} pr(D = k) = \sum\limits_a^A {{\beta _{ak}}{Z_i} + } \sum\limits_b^B {{\beta _{bk}}{X_i}} + {\varepsilon _i}. \end{equation}$$

Here, the unit of observation is the twin pair. Z is within-twin pair differences in variables that can differ between twins in the same pair, while X denotes variables that differ between twin pairs—that is, shared characteristics of a twin pair.

I estimate equation (4), the discordance treatment equations, as linear probability models using full-information maximum likelihood (FIML) with a robust covariance matrix in Stata 13. FIML uses all available information for each observation and builds the likelihood function casewise rather than imputing data, thus retaining all valid cases. It is preferred to multiple imputation for missing data for reasons detailed by Allison (Reference Allison2002). FIML is advantageous here because it allows one to recover substantial amounts of data missing at random due to the design of the MIDUS survey and to birth-weight non-response in particular (affecting around 50% of twin pairs). Discordance models estimated using list-wise deletion and a more basic set of covariates so as to preserve sample size (e.g., excluding birth weight) produced similar results for overall model fit. Results using a non-linear link function (e.g., logit) also produced the same substantive results.

Calculating inverse probability of treatment (IPT) weights for twin pairs

Using the discordance treatment equation parameter estimates, I calculate the estimated probability (propensity score) of each educational discrepancy for each twin pair and I use these to reweight the data, with the weights inversely proportional to the particular discrepancy (educational treatment) observed (Austin, Reference Austin2011; Malone et al., Reference Malone, Luciana, Wilson, Sparks, Hunt and Iacono2014, p. 411). The weights are stabilized by multiplying them by the proportion of pairs that received each treatment. Relative to unweighted or raw twin data, the weighted data more closely simulate a natural experiment on education, where educational treatment is orthogonal to participant characteristics.

Estimating returns to education using twin-pair fixed effects

In the final stage of analysis, I obtain fixed-effects (within-pair) estimates of midlife occupational and financial returns to education. Numerous methods are available for the regression-based analysis of twin data (Carlin et al., Reference Carlin, Gurrin, Sterne, Morley and Dwyer2005). When one desires simply to eliminate unobserved genetic and shared environmental heterogeneity, within-pair-differencing using identical twins is the most straightforward estimation strategy (Griliches Reference Griliches1979). Accordingly, I estimate equation 2 (above) by OLS through the origin with robust standard errors. Using both the unweighted and weighted data I obtain estimates of γ, the effect of education on the outcome, Y.